Tool for drilling/routing of printed circuit board materials

ABSTRACT

A dense cemented carbide product is described. The product is manufactured from WC with a grain size between 0.1 and 0.4 μm, fine grain size cobalt and ruthenium powders. The product is used in PCB machining operations where the addition of 10-25% Ru to the binder phase offers up to 25% wear resistant incrases and up to 100% increase in chipping resistance in PCB routing compared to conventional materials (6% cobalt and 0.4 μm grain size).

[0001] The present invention relates to a tool for drilling/routing of printed circuit board materials. By alloying the binder phase with Ru in combination with the use of fine grained Co-powder the properties have been improved.

[0002] Cemented carbide containing Ru as binder phase alone or in combination with the conventional Co and/or Ni is known in the art. For example, AT 268706 discloses a hard metal with Ru, Rh, Pd, Os, Ir, Pt and Re alone or in combination as binder phase. U.S. Pat. No. 4,574,011 discloses a hard metal composition for ornamental purposes with a binder phase of Co, Ni and Ru. GB 1309634 discloses a cutting tool with a Ru binder phase. GB 622041 discloses a hard metal composition a Co+Ru binder phase.

[0003] The routing of Printed Circuit Board materials requires a wide range of properties from the tool material in order for it to perform successfully. These include a hardness in excess of 2000 HV, a resistance to edge chipping that is best defined by a fracture toughness in excess of 8 MPam^(1/2), a resistance to chemical attack from the resins included in printed circuit boards and a sharp as possible a cutting edge. Some of these requirements conflict, for instance the high hardness tends to mean a reduced edge toughness. The new products for this application can, therefore, require a reduced WC grain size to produce a higher hardness with reduced toughness. However, if this is combined with an increase in cobalt content an increased toughness can be achieved for the same hardness. This also results in a sharper cutting edge, which is required.

[0004] The invention is primarily concerned with the addition of ruthenium to submicron grades of cemented carbide. The levels of addition vary between 5 and 35, preferably between 15 and 30, wt-% of the binder content with the best results obtained at about 25 wt-%. For best effects the cobalt used should be of the fine grain size cobalt powder having deagglomerated spherical grains of about 0.4 μm average grain size and with a narrow grain size distribution. Preferably the cobalt powder is polyol cobalt. The cobalt contents to which this addition can be made should vary from 5-12%, preferably 5-8. The average WC grain size shall be <0.8 μm, preferably <0.4 μm. The cemented carbide of the invention is preferably a straight WC+Co grade but it may also contain <5 wt-% gammaphase.

[0005] In order to obtain the submicron WC grain size VC+Cr₃C₂ is added. Because the Ru also acts as a mild grain growth inhibitor an addition of <0.9 wt % VC+Cr₃C₂ is generally satisfactory. Particularly good results are obtained if the VC/Cr₃C₂ ratio in wt % is 0.2-0.9, preferably 0.4-0.8, most preferably 0.6-0.7. Preferably sintering is performed using gas pressure sintering also referred to as sinter-HIP.

[0006] The invention also relates to the use of a cemented carbide with submicron WC grain size and with a binder phase containing 10-30 wt-% Ru as a tool for drilling/routing of printing circuit board materials.

[0007] The present invention further relates to a method of making a cemented carbide body comprising one or more hard constituents and a binder phase based on cobalt, nickel and/or iron by powder metallurgical methods milling, pressing and sintering of powders forming hard constituents and binder phase whereby said binder phase contains 10-30 wt-% Ru. At least part of the binderphase powder consists of non agglomerated particles of spheroidal morphology of about 0.4 μm average grain size and with a narrow grain size distribution wherein at least 80% of the particles have sizes in the interval x±0.2x provided that the interval of variation (that is 0.4x) is not smaller than 0.1 μm.

[0008] The advantages offered by the ruthenium additions are as mentioned a further element of grain growth refinement, an increase in resistance to chemical attack and a strengthening of the binder phase without significantly affecting the edge toughness due to the increase in cobalt content used.

EXAMPLE 1

[0009] Cemented carbide PCB-router according to the invention were made with the composition 1.9% Ru, 5.6% Cobalt the remainder WC (0.2 μm grain size), with about 0.7% (VC+Cr₃C₂) grain growth inhibitor. The material had a hardness of 2080HV and a KlC of 8.75 MPam^(1/2).

[0010] For comparison the following PCB routers according to prior art were also made. One was 6% cobalt grade with 0.4 μm WC with a hardness of 2000-2100 HV and one with the same hardness but with 5% cobalt and 0.5 μm WC grain size.

[0011] The routers were ground to 2.4 mm dia and tested as follows:

[0012] Workmaterial: Copper clad 3 mm thick FR4 PCB, stacked three deep

[0013] Test 1: 30,000 RPM, 1.2 m/min feedrate, 150 m of cut

[0014] Test 2: 42,000 RPM, 2.2 m/min feedrate, 100 m of cut

[0015] In test 1 routers according to the invention reached 150 m of cut with 25% less average wear than the prior art routers which used 6% cobalt.

[0016] In test 2 routers according to the invention reached 100 metres of cut with acceptable levels of wear.

[0017] Routers according to prior art with 5% and 6% cobalt both fractured between 50 and 75 metres.

EXAMPLE 2

[0018] 2.4 mm dia routers according to the invention were made from cemented carbides with varying ruthenium contents as follows:

[0019] Composition 1:1.0%Ru, 6.3%Co, 0.7VC+Cr₃C₂, 0.2 μm WC

[0020] Composition 2: 1.4%Ru, 6.0%Co, 0.7VC+Cr₃C₂, 0.2 μm WC

[0021] Composition 3: 1.9%Ru, 5.6%Co, 0.7VC+Cr₃C₂, 0.2 μm WC

[0022] The routers were tested as follows:

[0023] Workmaterial: Copper clad 3 mm thick FR4 PCB, stacked three deep

[0024] Conditions : 30,000 RPM, 1.2 m/min feed rate.

[0025] Machining until fracture.

[0026] Results:

[0027] 1.0%Ru variant—205 m (Average of 4 cutters)

[0028] 1.4%Ru variant—333 m (Average of 5 cutters)

[0029] 1.9%Ru variant—366 m (Average of 7 cutters)

EXAMPLE 3

[0030] Cemented carbide PCB microdrills according to the invention were made with the composition 2.2% Ru, 6.4% Co the remainder WC (0.4 μm grain size), with about 0.8% (VC+Cr₃C₂) grain growth inhibitor. The material had a hardness of 2010HV and a KlC of 8 MPam^(1/2).

[0031] For comparison the following PCB micro drills according to prior art were made using 8% cobalt grade with 0.4 μm WC with a hardness of 1900HV.

[0032] The microdrills were tested and the wear measured. It was found that the prior art materials exhibited 10-15% less wear resistance and 10-15% less resistance to breakage during an increasing feed rate that started at 15 μm/rev and increasing towards 70. 

1. Cemented carbide for PCB-drills containing 5-12% Co binder phase and remainder submicron WC characterised in that said binder phase further contains 10-30 wt-% Ru.
 2. Cemented carbide according to the preceding claim characterised in that the binder phase content is 5-8 wt-%.
 3. Cemented carbide according to any of the preceding claim characterised in that said binder phase further contains about 25 wt-% Ru.
 4. Use of a cemented carbide with submicron WC grain size and with 5-12% Co binder phase containing 10-30 wt-% Ru as a tool for machining of printed electronic circuit boards and similar composite materials.
 5. Method of making a cemented carbide body comprising one or more hard constituents and a binder phase based on cobalt, nickel and/or iron by powder metallurgical methods milling, pressing and sintering of powders forming hard constituents and binder phase whereby said binder phase contains 10-30 wt-% Ru characterized in that at least part of the binderphase powder consists of non agglomerated particles of spheroidal morphology of about 0.4 μm average grain size and with a narrow grain size distribution wherein at least 80% of the particles have sizes in the interval x±0.2x provided that the interval of variation (that is 0.4x) is not smaller-than 0.1 μm. 